Fully corrected assorted $\pi^{0}$-hadron conditional pair distributions for $d$+Au collisions centrality 0-88% and $p$+$p$ collisions. The trigger $\pi^0$s are within 5 < $p_{T,trig}$ < 10 GeV/$c$ and are correlated with hadrons with $p_{T,assoc}$ of 1.5-2 GeV/$c$, 2-3GeV/$c$, 3-4 GeV/$c$, and 4-5 GeV/$c$.

Near- and far-side widths as a function of $p_{T, assoc}$ for charged hadron azimuthal correlations from minimumbias $d$+Au collisions.

Near-side width, far-side width as a function of $p_{T,assoc}$ for a charged pion and neutral pion triggers from the $p_{T,trig}$ range of 5-10 GeV/$c$ in minimum bias $d$+Au collisions.

Near-side width, far-side width as a function of $p_{T,assoc}$ for a charged pion and neutral pion triggers from the $p_{T,trig}$ range of 5-10 GeV/$c$ in minimum bias $d$+Au collisions.

Near- and far-side conditional yields as a function of $p_{T, assoc}$ for charged hadron triggers (2.5−4 GeV/$c$) and associated charged hadrons from $d$+Au collisions.

Near- and far-side conditional yields as a function of $p_{T, assoc}$ for charged hadron triggers (4−6 GeV/$c$) and associated charged hadrons from $d$+Au collisions.

Near- and far-side conditional yields as a function of $p_{T, assoc}$ for charged pion triggers (5−10 GeV/$c$) and associated charged hadrons from minimum-bias $d$+Au collisions.

Near- and far-side conditional yields as a function of $p_{T, assoc}$ for neutral pion triggers (5−10 GeV/$c$) and associated charged hadrons from minimum-bias $d$+Au collisions.

Near- and far-side widths and conditional yields as a function of $N_{coll}$ for charged hadron triggers (2.5−4 GeV/$c$) and associated charged hadrons (1–2.5 GeV/$c$) from $d$+Au collisions.

Near- and far-side widths and conditional yields as a function of centrality for neutral pion triggers (5−10 GeV/$c$) and associated charged hadrons (2–3 GeV/$c$) from $d$+Au collisions.

The extracted $\sqrt{<j^2_T>}$ for minimum-bias $d$+Au collisions from all four dihadron correlations. The trigger $p_T$ ranges are 3 - 5 GeV/$c$, 5 - 10 GeV/$c$ and 5 - 10 GeV/$c$ for $h^{\pm}$ - $h^{\pm}$, $\pi^0$ - $h^{\pm}$ and $\pi^{\pm}$ - $h^{\pm}$ assorted-$p_T$ correlations.

The extracted $\sqrt{<j^2_T>}$ for minimum-bias $d$+Au collisions from all four dihadron correlations. The trigger $p_T$ ranges are 3 - 5 GeV/$c$, 5 - 10 GeV/$c$ and 5 - 10 GeV/$c$ for $h^{\pm}$ - $h^{\pm}$, $\pi^0$ - $h^{\pm}$ and $\pi^{\pm}$ - $h^{\pm}$ assorted-$p_T$ correlations.

The extracted $\sqrt{<j^2_T>}$ for minimum-bias $d$+Au collisions from all four dihadron correlations. The trigger $p_T$ ranges are 3 - 5 GeV/$c$, 5 - 10 GeV/$c$ and 5 - 10 GeV/$c$ for $h^{\pm}$ - $h^{\pm}$, $\pi^0$ - $h^{\pm}$ and $\pi^{\pm}$ - $h^{\pm}$ assorted-$p_T$ correlations.

The extracted $\sqrt{<j^2_T>}$ for minimum-bias $d$+Au collisions from all four dihadron correlations. The trigger $p_T$ ranges are 3 - 5 GeV/$c$, 5 - 10 GeV/$c$ and 5 - 10 GeV/$c$ for $h^{\pm}$ - $h^{\pm}$, $\pi^0$ - $h^{\pm}$ and $\pi^{\pm}$ - $h^{\pm}$ assorted-$p_T$ correlations.

$<sin^2(\phi_{jj})>$ for minimum bias $d$+Au collisions as function of associated particle $p_T$ for $\pi^{\pm}$ - $h^{\pm}$ and $\pi^0$ - $h^{\pm}$ correlations where the trigger particles have a $p_T$ between 5 - 10 GeV/$c$.

$<sin^2(\phi_{jj})>$ for minimum bias $d$+Au collisions as function of associated particle $p_T$ for $\pi^{\pm}$ - $h^{\pm}$ and $\pi^0$ - $h^{\pm}$ correlations where the trigger particles have a $p_T$ between 5 - 10 GeV/$c$.

$<sin^2(\phi_{jj})>$ for minimum bias $d$+Au collisions as function of trigger particle $p_T$ for $\pi^{\pm}$ - $h^{\pm}$ and $\pi^0$ - $h^{\pm}$ correlations.

$<sin^2(\phi_{jj})>$ for minimum bias $d$+Au collisions as function of trigger particle $p_T$ for $\pi^{\pm}$ - $h^{\pm}$ and $\pi^0$ - $h^{\pm}$ correlations.

Near-side and far-side $p_{out}$ distributions for minimum bias $d$+Au collisions obtained from $\pi^{\pm}$ - $h^{\pm}$ correlation. The trigger is 5 < $p_{T,trig}$ < 10 GeV/$c$, the associated particle is 0.5 < $p_{T,assoc}$ < 5.0 GeV/$c$.

Conditional yield as a function of $x_E$ for near-side and far-side for $\pi^{\pm}$ - $h^{\pm}$ and $\pi^0$ - $h^{\pm}$ from minimum-bias $d$+Au collisions.

Conditional yield as a function of $x_E$ for near-side and far-side for $\pi^{\pm}$ - $h^{\pm}$ and $\pi^0$ - $h^{\pm}$ from minimum-bias $d$+Au collisions.

Conditional yield as a function of $x_E$ for near-side and far-side correlations for $\pi^{\pm}$ - $h^{\pm}$ correlations from minimum-bias $d$+Au collisions. The trigger pions are 5 < $p_{T,trig}$ < 6 GeV/$c$.

Conditional yield as a function of $x_E$ for near-side and far-side correlation for $\pi^{\pm}$ - $h^{\pm}$ correlation for several different trigger $p_T$s for minimum-bias $d$+Au collisions.

Far-side conditional yield as a function of $p_{T,trig}$ for different ranges of $x_E$ for $\pi^{\pm}$ - $h^{\pm}$ correlation for minimum-bias $d$+Au collisions.

Far-side conditional yield as a function of $p_{T,trig}$ for different ranges of $x_E$ for $\pi^{\pm}$ - $h^{\pm}$ correlation for minimum-bias $d$+Au collisions.

Far-side conditional yield as a function of $p_{T,trig}$ for different ranges of $x_E$ for $\pi^{\pm}$ - $h^{\pm}$ correlation for minimum-bias $d$+Au collisions.

Far-side conditional yield as a function of $p_{T,trig}$ for different ranges of $x_E$ for $\pi^{\pm}$ - $h^{\pm}$ correlation for minimum-bias $d$+Au collisions.

The comparison of the $\sqrt{<j^2_T>}$ values between $d$+Au and $p$+$p$ for the $\pi^{\pm}$ - $h^{\pm}$ correlations and $\pi^0$ - $h^{\pm}$ correlations. The trigger pion range is 5 - 10 GeV/$c$.

The comparison of the $\sqrt{<j^2_T>}$ values between $d$+Au and $p$+$p$ for the $\pi^{\pm}$ - $h^{\pm}$ correlations and $\pi^0$ - $h^{\pm}$ correlations. The trigger pion range is 5 - 10 GeV/$c$.

Quadrature difference between minimum-bias $d$+Au and $p$+$p$ $<sin^2(\phi_{jj})>$ values.

Quadrature difference between minimum-bias $d$+Au and $p$+$p$ $<sin^2(\phi_{jj})>$ values.

The comparison of the $p_{out}$ distribution at the near-side and far-side between central $d$+Au collisions and $p$+$p$ collisions. Results are obtained for $\pi^{\pm}$ - $h^{\pm}$ correlations with the associated hadron range 0.5 < $p_{T,assoc}$ < 5 GeV/$c$ and trigger pion range of 5 < $p_{T,trig}$ < 10 GeV/$c$.

The comparison of the $x_E$ distribution from $\pi^{\pm}$ - $h^{\pm}$ correlation at the near-side and far-side between minimum bias $d$+Au collisions and $p$+$p$ collisions. The trigger $\pi^{\pm}$ are from 5 - 10 GeV/$c$.

Far-side conditional yield as a function of $p_{T,trig}$ for different ranges of $x_E$ from $p$+$p$ collisions, triggers are $\pi^{\pm}$ from 5 - 10 GeV/$c$.

Far-side conditional yield as a function of $p_{T,trig}$ for different ranges of $x_E$ from $p$+$p$ collisions, triggers are $\pi^{\pm}$ from 5 - 10 GeV/$c$.

Far-side conditional yield as a function of $p_{T,trig}$ for different ranges of $x_E$ from $p$+$p$ collisions, triggers are $\pi^{\pm}$ from 5 - 10 GeV/$c$.

The fitted fractional change in $dN/d_{x_E}$ per unit $p_{T,trig}$ of the far-side conditional yield for different ranges of $x_E$.

Centrality dependent near and far $CY(p_T)$ for $\pi^{\pm}$ - $h^{\pm}$ correlations and $\pi^0$ - $h^{\pm}$ correlations.

Centrality dependent near and far $CY(p_T)$ for $\pi^{\pm}$ - $h^{\pm}$ correlations and $\pi^0$ - $h^{\pm}$ correlations.

Centrality dependence to the ratio of near and far $CY(p_T)$ for $d$+Au to $p$+$p$.

Centrality dependence to the ratio of near and far $CY(p_T)$ for $d$+Au to $p$+$p$.

Near- and far-side widths as a function of $p_{T, trig}$ for charged pion triggers and associated charged hadrons (2–4.5 Gev/$c$) from minimum-bias $d$+Au collisions.

Near- and far-side widths as a function of $p_{T, trig}$ for neutral pion triggers and associated charged hadrons (2–4.5 Gev/$c$) from minimum-bias $d$+Au collisions.

Measurement of F2 at X = 0.125.

Measurement of F2 at X = 0.175.

Measurement of F2 at X = 0.225.

Measurement of F2 at X = 0.275.

Measurement of F2 at X = 0.350.

Measurement of F2 at X = 0.450.

Measurement of F2 at X = 0.550.

Measurement of F2 at X = 0.650.

Measurement of F2 at X = 0.750.

Measurement of XF3 at X = 0.015.

Measurement of XF3 at X = 0.045.

Measurement of XF3 at X = 0.080.

Measurement of XF3 at X = 0.125.

Measurement of XF3 at X = 0.175.

Measurement of XF3 at X = 0.225.

Measurement of XF3 at X = 0.275.

Measurement of XF3 at X = 0.350.

Measurement of XF3 at X = 0.450.

Measurement of XF3 at X = 0.550.

Measurement of XF3 at X = 0.650.

Measurement of XF3 at X = 0.750.

Differential cross sections at neutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at neutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at neutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at neutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at neutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 35.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 45.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 55.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 65.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 75.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 85.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 95.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 110.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 130.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 150.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 170.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 190.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 215.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 245.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 275.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

Differential cross sections at antineutrino energy 305.0 GeV as a function of inelasticity Y for X values 0.550, 0.650 and 0.750.

Differential cross sections at antineutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.015, 0.045 and 0.080.

Differential cross sections at antineutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.125, 0.175 and 0.225.

Differential cross sections at antineutrino energy 340.0 GeV as a function of inelasticity Y for X values 0.275, 0.350 and 0.450.

The ratio of the hadronic decay photon $v_2$ over inclusive photon $v_2$ ($v_2^{b.g}/v_2^{inclusive \gamma}$) compared with the direct photon excess ratio $R = (N_{direct \gamma} + N_{b.g})/N_{b.g}$.

The ratio of the hadronic decay photon $v_2$ over inclusive photon $v_2$ ($v_2^{b.g}/v_2^{inclusive \gamma}$) compared with the direct photon excess ratio $R = (N_{direct \gamma} + N_{b.g})/N_{b.g}$.

Cross section as a function of the jet transverse energy for INCLUSIVE events containing at least one D* meson in different jet pseudorapidity regions.

Cross section as a function of the jet transverse energy for INCLUSIVE events containing at least one D* meson in different jet pseudorapidity regions.

Cross section as a function of the jet pseudorapidity for INCLUSIVE events containing at least one D* meson in different jet transverse energy regions.

Cross section as a function of the jet pseudorapidity for INCLUSIVE events containing at least one D* meson in different jet transverse energy regions.

Cross section as a function of the jet pseudorapidity for INCLUSIVE events containing at least one D* meson in different jet transverse energy regions.

Cross section as a function of the jet transverse energy for D*-TAGGED and UNTAGGED jets in the jet pseudorapidity region -1.5 TO 2.4.

Cross section as a function of the jet pseudorapidity for D*-TAGGED and UNTAGGED jets in 3 regions of jet transverse energy.

Cross section as a function of the jet pseudorapidity for D*-TAGGED and UNTAGGED jets in 3 regions of jet transverse energy.

Cross section as a function of the jet pseudorapidity for D*-TAGGED and UNTAGGED jets in 3 regions of jet transverse energy.

Cross section as a function of the jet transverse energy in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet transverse energy in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet transverse energy in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet pseudorapidity in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet pseudorapidity in 3 regions of transverse momentum of the D*.

Cross section as a function of the jet pseudorapidity in 3 regions of transverse momentum of the D*.

Cross section as a function of XOBS(C=GAMMA,D*,JET) where the jet here is the UNTAGGED jet with the lightest ET.

The dijet cross section as a function of XOBS(C=GAMMA) for events containing at least one D* meson.

The dijet cross section as a function of the PHI angle difference in JET1 and JET2 for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the PHI angle difference in JET1 and JET2 for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the PHI angle difference in JET1 and JET2 for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the 2-jet transverse momentum for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the 2-jet transverse momentum for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the 2-jet transverse momentum for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the the 2-jet mass for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the the 2-jet mass for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

The dijet cross section as a function of the the 2-jet mass for events containing at least one D* meson in different XOBS(C=GAMMA) regions.

Mean PT^2 values at negative, null and positive XF for D+AU reaction The mean PT is obtained with a phenomenological fit of the J/PSI distribution in PT of the form (1/(2*PI*PT))*D2(SIG)/DPT*DY = A ( 1+(PT/B)^2)^-6.

Mean PT^2 values at negative,null and positive XF for P+P reaction The mean PT is obtained with a phenomenological fit of the J/PSI distribution in PT of the form (1/(2*PI*PT))*D2(SIG)/DPT*DY = A ( 1+(PT/B)^2)^-6.

PT dependence of the Alpha power for Xf ~ -0.08.

PT dependance of the Alpha power for Xf ~ 0.

PT dependance of the Alpha power for Xf ~ 0.09.

Centrality dependance of the Nuclear modification factor for rapidity : y=-1.7. Centrality is represented by the number of collisions.

Centrality dependance of the Nuclear modification factor for rapidity y=0.Centrality is represented by the number of collisions.

Centrality dependance of the Nuclear modification factor for rapidity y=1.8.Centrality is represented by the number of collisions.